Evolutionarily conserved replication timing profiles predict long-range chromatin interactions and distinguish closely related cell types

Ryba, Tyrone; Hiratani, Ichiro; Lu, Junjie; Itoh, Mari; Kulik, Michael; Zhang, Jinfeng; Schulz, Thomas C.; Robins, Allan J.; Dalton, Stephen; Gilbert, David M.

doi:10.1101/gr.099655.109

Cited by 548 publications

(771 citation statements)

References 49 publications

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“…Because cancers usually occur beyond the reproductive age, cancer traits would not be under direct selection pressure. However, many cancer-related genes are often involved in fundamental cellular processes such as development, cell cycle, and DNA repair, and these genes tend to be in early replicating regions 34 . A recent study has shown that replication timing is an evolvable property 35 .…”

Section: Discussionmentioning

confidence: 99%

DNA replication timing and selection shape the landscape of nucleotide variation in cancer genomes

2012

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Cancer cells evolve from normal cells by somatic mutations and natural selection. Comparing the evolution of cancer cells and that of organisms can elucidate the genetic basis of cancer. Here we analyse somatic mutations in > 400 cancer genomes. We find that the frequency of somatic single-nucleotide variations increases with replication time during the s phase much more drastically than germ-line single-nucleotide variations and somatic large-scale structural alterations, including amplifications and deletions. The ratio of nonsynonymous to synonymous single-nucleotide variations is higher for cancer cells than for germ-line cells, suggesting weaker purifying selection against somatic mutations. Among genes with recurrent mutations only cancer driver genes show evidence of strong positive selection, and late-replicating regions are depleted of cancer driver genes, although enriched for recurrently mutated genes. These observations show that replication timing has a prominent role in shaping the single-nucleotide variation landscape of cancer cells.

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Section: Discussionmentioning

confidence: 99%

DNA replication timing and selection shape the landscape of nucleotide variation in cancer genomes

2012

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“…The Hi-C study proposed that the genome is divided into two distinct compartments, an open compartment characterized by euchromatic features, such as histone 3 lysine 4 (H3K4) trimethlyation, and a closed compartment characterized by heterochromatic features, such as H3K9 methylation [120]. Importantly, DNA replication correlates to 3-D genome organization even more so than to transcription, with early replicating regions being mostly in the euchromatic compartment and late replicating ones in the heterochromatic one [116,121]. Thus, lack of global reorganization of DNA replication in preiPS cells might reflect a not properly reorganized global 3-D nuclear architecture, suggesting that nuclear architecture might be another barrier for reprogramming that is closely associated with replication timing control.…”

Section: Resetting Of Dna Replicationmentioning

confidence: 99%

Reprogramming to pluripotency: stepwise resetting of the epigenetic landscape

2011

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In 2006, the "wall came down" that limited the experimental conversion of differentiated cells into the pluripotent state. In a landmark report, Shinya Yamanaka's group described that a handful of transcription factors (Oct4, Sox2, Klf4 and c-Myc) can convert a differentiated cell back to pluripotency over the course of a few weeks, thus reprograming them into induced pluripotent stem (iPS) cells. The birth of iPS cells started off a rush among researchers to increase the efficiency of the reprogramming process, to reveal the underlying mechanistic events, and allowed the generation of patient-and disease-specific human iPS cells, which have the potential to be converted into relevant specialized cell types for replacement therapies and disease modeling. This review addresses the steps involved in resetting the epigenetic landscape during reprogramming. Apparently, defined events occur during the course of the reprogramming process. Immediately, upon expression of the reprogramming factors, some cells start to divide faster and quickly begin to lose their differentiated cell characteristics with robust downregulation of somatic genes. Only a subset of cells continue to upregulate the embryonic expression program, and finally, pluripotency genes are upregulated establishing an embryonic stem cell-like transcriptome and epigenome with pluripotent capabilities. Understanding reprogramming to pluripotency will inform mechanistic studies of lineage switching, in which differentiated cells from one lineage can be directly reprogrammed into another without going through a pluripotent intermediate.

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“…As noted above, studies of nascent sites within nuclei show that a specific subset of potential initiation targets are select with good efficiency at the onset of the S phase (Jackson and Pombo 1998;Ma et al 1998). Numerous genome-wide studies have shown that active genes are preferentially replicated at the beginning of the S phase and the process of selection correlates with patterns of gene expression (Cadoret et al 2008;Farkash-Amar et al 2008), active chromatin marks (Hiratani et al 2008), and the mostly highly interactive gene regions defined by Hi-C (Ryba et al 2010). These observations imply that the local chromatin context is a key determinant of initiation at the onset of the S phase, with arguably the most mobile chromatin having the highest probability of engaging synthesis.…”

Section: S-phase Progressionmentioning

confidence: 73%

“…The underlying mechanisms that define these structures are likely to be very complex, so that the structure of chromatin domains correlates with numerous features of chromatin function. This is especially evident during cell differentiation, when subtle changes in higher-order chromatin architecture during differentiation provide an excellent correlation with changes in replication timing (Ryba et al 2010). …”

Section: Replication In Bacteria and Eukaryotesmentioning

confidence: 99%

Spatio-Temporal Organization of Replication in Bacteria and Eukaryotes (Nucleoids and Nuclei)

Jackson

Wang²,

Rudner³

2012

Cold Spring Harbor Perspectives in Biology

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Here we discuss the spatio-temporal organization of replication in eubacteria and eukaryotes. Although there are significant differences in how replication is organized in cells that contain nuclei from those that do not, you will see that organization of replication in all organisms is principally dictated by the structured arrangement of the chromosome. We will begin with how replication is organized in eubacteria with particular emphasis on three well studied model organisms. We will then discuss spatial and temporal organization of replication in eukaryotes highlighting the similarities and differences between these two domains of life.

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Evolutionarily conserved replication timing profiles predict long-range chromatin interactions and distinguish closely related cell types

Cited by 548 publications

References 49 publications

DNA replication timing and selection shape the landscape of nucleotide variation in cancer genomes

DNA replication timing and selection shape the landscape of nucleotide variation in cancer genomes

Reprogramming to pluripotency: stepwise resetting of the epigenetic landscape

Spatio-Temporal Organization of Replication in Bacteria and Eukaryotes (Nucleoids and Nuclei)

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